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At the corner of the cube circular arcs are drawn and the area enclosed shaded. What fraction of the surface area of the cube is shaded? Try working out the answer without recourse to pencil and paper.

At the beginning of the night three poker players; Alan, Bernie and Craig had money in the ratios 7 : 6 : 5. At the end of the night the ratio was 6 : 5 : 4. One of them won $1 200. What were the assets of the players at the beginning of the evening?

BUT wouldn't it be simpler to write it as the sum of just two different unit fractions?

But is it always so easy?
Try some other fractions with a numerator of 2.
Can they also be written as the sum of just two different unit fractions?

Can all fractions with a numerator of 2 (i.e. of the form $\frac{2}{n}$) be written as the sum of just two different unit fractions?

Can you find an efficient method for doing this?

You might want to explore fractions of the form $\frac{3}{n}$, $\frac{4}{n}$, $\frac{5}{n}$...... and think about how the Egyptians would have represented these, using sums with the least number of unit fractions.

The ancient Egyptians lived thousands of years ago, how do we know what they thought about numbers? A little research on this topic will show that famous mathematicians have asked and answered questions about the Egyptian fraction system for hundreds of years. You can find references to results in this field that were proved in the 1200s and in the 2000s, and you can also find some open questions
- things mathematicians think are true, but have not been proved yet.

Throughout history, different civilisations have had different ways of representing numbers. Some of these systems seem strange or complicated from our perspective. The ancient Egyptian ideas about fractions are quite surprising.

For example, they wrote $\frac{1}{5}$, $\frac{1}{16}$ and $\frac{1}{429}$ as
(but using their numerals)

They didn't write fractions with a numerator greater than 1 - they wouldn't, for example,write $\frac{2}{7}$, $ \frac{5}{9}$, $ \frac{123}{167}$.... although there is evidence that the specific fraction $\frac{2}{3}$ was used by the Egyptians, and $\frac{3}{4}$ sometimes as well. They had special symbols for these two fractions.

The Rhind Mathematical Papyrus is an important historical source for studying Egyptian fractions - it was probably a reference sheet, or a lesson sheet and contains Egyptian fraction sums for all the fractions $\frac{2}{3}$, $ \frac{2}{5}$, $ \frac{2}{7}... \frac{2}{101}$.
Why did they only include the odd ones?

$\frac{4}{n}$ and $\frac{3}{n}$

In the 1940s, the mathematicians Paul Erdos and Ernst G. Straus conjectured that every fraction with numerator = 4 can be written as an Egyptian fraction sum with three terms. If you have found an example that appears to need more than three, can you find an alternative sum? Can you find a reason why it must work, or a counter-example - the conjecture isn't yet proved. It is proved for
$\frac{3}{n}$.

The NRICH Project aims to enrich the mathematical experiences of all learners. To support this aim, members of the
NRICH team work in a wide range of capacities, including providing professional development for teachers wishing to
embed rich mathematical tasks into everyday classroom practice. More information on many of our other activities
can be found here.